Tag Archives: atmosphere
India, Pakistan leaders reach no concrete agreements
India, Pakistan leaders reach no concrete agreements (Reuters) / 30 September 2013 Indian Prime Minister Manmohan Singh and his Pakistani counterpart, Nawaz Sharif, agreed on Sunday to work to restore a cross-border ceasefire after a spate of shootings in order to improve strained ties, officials said. Singh and Sharif met on the sidelines of the United Nations General Assembly, amid heightened tension between the nuclear-armed neighbours over the Kashmir region, sparked by series of fatal clashes on their de facto Himalayan border. India emerged from the meeting of more than an hour calling the talks “useful” while Pakistan called the atmosphere “very positive.” They both expressed a desire to improve ties but agreed that “peace and tranquillity across the LOC (Line of Control) is a precondition,” Indian national security adviser Shivshankar Menon told reporters in New York. “We need to address the issues that we face today and then we hope to move it forward,” he said. Pakistan’s Secretary for Foreign Affairs Jalil Abbas Jilani told reporters the New York meeting set the stage for future cooperation even though they did not reach specific agreements. “The most significant aspect of the meeting was that the leaders expressed their commitment to … better relations between the two countries,” he told reporters at a separate New York briefing. “Both sides wish to see a better India-Pakistan relationship than we have today,” said Menon. A series of fatal clashes along the so-called Line of Control dividing Kashmir between India and Pakistan have killed at least eight soldiers from both countries in less than two months. The South Asia Terrorism Portal, a website that tracks the violence, says this year’s toll is 44 members of the security forces, up from 17 for all of last year. In their speeches to the U.N. General Assembly, both leaders said they wanted to improve relations between their countries, which have fought three wars since becoming independent from Britain in 1947, two of them over Kashmir. The two prime ministers agreed to instruct military officials to work together to develop a mechanism to stop ceasefire violations, Menom and Jalil said. The two leaders accepted invitations to visit each other’s countries, but no dates were set, Menon added. Continue reading
Biochar: Black Gold or Just Another Snake Oil Scheme?
BY RACHEL SMOLKER – SEPTEMBER 18, 2013 There’s little basis for claims that biochar could solve our energy, food, and climate woes In an interview with Naomi Klein , published in the Autumn 2013 issue of Earth Island Journal , she referred to the American fondness for “win-win solutions.” I had to giggle, having on many occasions sat in on industry-led events, where the speakers, wildly animated, blather on about their latest “win-win-win” technofix, certain to resolve everything that ails humanity, from climate change to poverty, to deforestation to toxic pollution to nuclear waste. Who could be against such hopeful, all-in-one miracle cures? Perhaps only the skeptics who know the smell of snake oil. Which, I guess, includes me. Photo by potaufeu/flickr Field trail results fly in the face of repeated claims that biochar will sequester carbon in soils for tens, hundreds or even thousands of years. I came to such deep skepticism not by nature but from years of experience. One formative experience has been following the hype around biochar. Biochar enthusiasts are a hopeful bunch. They claim that charred biomass will be a win for climate, a win for soils and crop yields, hence a win against hunger and poverty, and a win for renewable energy generation. They are convinced that burning “biomass,” that is, trees, crop residues, animal manure or what have you, (some even advocate burning garbage or tires ), could solve our energy, food, and climate woes. Right away, there is good reason to be skeptical. Burning anything at all seems an unlikely cure for an overheating planet. No matter how it is done, or what is burned, combustion creates pollution — air pollution, particulates, ashes, various toxins and soot, the second largest warming agent after C02. Nonetheless, there are many who embrace biochar and specifically advocate burning things under oxygen starved conditions, via process called pyrolysis, to maximize the production of charred residues. Biochar, they claim, is “black gold.” *** The first key “win” of biochar, proponents say, is that if buried in the ground, the char, which consists largely of carbon, will more or less permanently “sequester” that carbon and therefore help to cleanse the atmosphere. In an article published in the journal, Nature, some of the leading biochar enthusiasts claimed that it could offset global greenhouse gas emissions by a whopping 12 percent annually. All that would be required is collecting most forest and agriculture residues and animal manures from across the globe, as well as converting over half a billion hectares (an area larger than India) of land to producing dedicated burnable crops. After collecting it, the biomass would be transported to pyrolysis facilities, burned, then the char would be collected and transported back around the globe where it would be tilled and buried into soils over millions of acres. Year after year. The problem with this idea isn’t just the massive scale of the project, for which there seems little social or political will. It is even more fundamental: There is really little basis for assuming that biochar carbon really will store carbon reliably in soils. A Biofuelwatch review of peer-reviewed field trials as of 2011 showed some remarkably unimpressive results. We only looked at peer-reviewed field trials in order to distinguish clearly between hype and actual results, and to discern how biochar acts in the real world, with living biodiverse soils, rather than sterile, laboratory conditions. Field trails proved rare; only five such studies were found, which between them tested biochar on 11 different combinations of soil and vegetation. In only three cases did biochar result in any additional carbon sequestration. In most cases, there was either no measurable difference in soil carbon, or even a reduction in soil carbon. These results from short-term studies —none spanned more than four years — fly in the face of repeated claims that biochar will sequester carbon in soils for tens, hundreds or even thousands of years. Photo by crustmania/flickr Biochar enthusiasts claim it can improve the quality of the soil and hence improve crop yields and thereby help reduce desertification and deforestation. More recently, two important reviews (you can read them here and here ) of soil carbon showed that the stability of soil carbon is not so much determined by the molecular structure of the carbon itself, but rather by surrounding soil ecosystem properties. That makes reliable carbon storage very difficult to predict or assume. Win number two, biochar enthusiasts claim, is that biochar will also improve the quality of the soil and hence improve crop yields, thereby help reduce desertification, deforestation, hunger, and poverty. Again, Biofuelwatch’s review of peer reviewed field trials showed unimpressive and erratic results. Since then, a recent synthesis review of impact on crop yields found that in half of published studies, there was either no effect whatsoever on crop yields, or biochar actually reduced yields. The third win, according to advocates, is generating renewable electricity and heat during pyrolysis. But so far, virtually all biochar has been produced without doing so. That’s because pyrolysis is difficult to control and remains largely unproven for commercial application. Another reason is the inherent trade off: If you want more biochar less biomass will be converted to heat and power, and vice versa. None of these trial results have dampened the hopes of biochar enthusiasts, who still see wins everywhere they look. They continue to promote biochar as a means to reduce fertilizer demand, agricultural runoff, clean up waste water, reclaim mine sites, and offset fossil fuel pollution. Some have even advocated feeding it to cows to make them emit less gas, and one company even claims that biochar will make it possible for consumers to reduce greenhouse gas emissions even while driving big gas-guzzling cars. (see below). In her Journal interview Klien also spoke about climate geoengineering, which she referred to as a proverbial “escape hatch” providing a way to avoid the consequences of our failure to reduce greenhouse gas emissions. This is indeed one of the most perilous hazards of the geoengineering mindset. Widespread doubts about geoengineering have resulted in a push to accept “more benign” technologies, including large-scale biochar and bioenergy with carbon capture and storage (BECCS). Both biochar and BECCS require burning lots of biomass — trees and crops, as well as municipal solid waste. Staggering quantities would have to be harvested and burned to have any measureable impact on the global atmosphere. Studies have shown that capturing just one billion tonnes of carbon per year would require conversion of up to 990 million hectares of land to plantations. The consequences for land, water, soils, biodiversity, would very likely render the treatment worse than the disease. What is already painfully evident is that demand for biomass, even at the current smaller scale is already stripping Earth of her remaining biodiverse ecosystems, and replacing them with industrial, chemically-dependent monoculture deserts. Another article in the Journal’s recent issue, “ Modified Stands ,” talks about the push for genetically engineered trees. The impetus behind GE trees is a projected dramatic increase in demand for wood, in large part for bioenergy. This demand is a result of subsidies and supports for renewable energy that fail to distinguish between the kind of renewable energy that requires constant inputs of fuel (wood etc) and combustion, and the kind that does not. The l ion’s share of subsidies and supports has gone to bioenergy, including biofuels and biomass burning for electricity, which can conveniently be done 24/7 in coal plants, or stand alone facilities. Windmills and solar panels are more fussy , expensive, and their production cycles are intermittent. To get a sense of the scale and impact of using bioenergy, consider that in the United Kingdom alone, current and proposed biomass burning for energy would require over 80 million tons of wood, more than eight times the amount of wood produced for all purposes domestically. There is now an expanding international trade in wood chips and pellets to satisfy this voracious demand from the UK and other European countries. Tree plantations and native forests in the southeastern United States and Canada are being cut, pelletized and shipped to Europe to be burned as “renewable energy.” The wood pellet industry is booming, and fast growing monoculture plantations — which could soon include GE trees, are in great demand. Biochar enthusiasts usually insist they won’t cut forests or convert ecosystems to provide burnable biomass. Just like the biomass electricity industry, they prefer to talk about burning “wastes and residues.” But there is no such thing as “waste” in a forest ecosystem — all is recycled, via decay, to support regeneration and regrowth. In many places, definitions of waste have been expanded to include virtually any wood that is not valued as sawlogs, so timber harvests are more intense and destructive. In agriculture, there are often better options for residues, such as compost, mulch, animal fodder, and bedding. In any case, industrial forestry and agriculture practices have already wreaked havoc on ecosystems. Creating a market for the waste products of unsustainable practices hardly seems a step in the right direction. *** Photo by Engineering for Change A biomass briquette. There is an inherent trade off between using biomass to produce biochar vs using it to produce energy: If you want more biochar less biomass will be converted to heat and power, and vice versa. So far, biochar has not gained the subsidies and investments needed to scale it up commercially. Biochar advocates initially worked to gain funding from carbon markets, arguing that biochar could “offset” fossil fuel pollution, but with the recent decline of global carbon markets they have largely retreated seeking carbon financing. Instead, they are now pushing biochar as a niche product for small-scale and organic farmers. The good news is that most small-scale farmers are closely attuned to what works on their farms and will judge for themselves. The bad news is that they are largely unaware that they are to some extent being used to promote an eventual massive scale-up of the biochar industry. In 2008-09, for example, a high-profile biochar project in Cameroon run by Biochar Fund, a Belgian nonprofit, promised to alleviate poverty and improve nutritional status of poor farmers by improving crop yields. The farmers donated land and labor, and were told they would be compensated with finance from carbon markets. The first set of trials were proclaimed wildly successful without any independent verification. Then the trials were abandoned without even informing the farmers. Biochar Fund moved on and was granted funds for yet another set of trials in Congo. This time the claim was that biochar would enable slash and burn agriculturalists to do less slashing and burning because the soils would be enriched with biochar. So far, there are no reports of the status of those trials. (Read Biofuelwatch’s investigative report about the Cameroon project here. ) Just as with biomass electricity, biochar enthusiasts claim that burning biomass is “carbon neutral” – that the carbon released during combustion will be reabsorbed by new trees or crops. This claim has been soundly and repeatedly refuted . Trees take years to regrow, assuming that they even do so. Cutting natural forests for biomass electricity, or biochar, or any other use results in a massive “ carbon debt ” that can take decades or even centuries to repay (i.e. for an equivalent amount of carbon to be reabsorbed in new tree growth). Biochar advocates continue to cling to the carbon neutral myth nonetheless. In fact, they take it a step further. Burying the carbon char in soils, they say, will permanently store some of the carbon, so regrowth will absorb additional (not just replacement) carbon. This, they say, makes it carbon negative. This misguided logic is what lies behind claims by companies like Cool Planet that consumers can clean the atmosphere by driving more. The California-based biofuel and biochar company seeks to make transportation fuels from wood, which they say is “carbon neutral,” and then bury the char residue from their production process, thus renderning the entire process “carbon negative.” By Cool Planet’s logic, driving more could actually reduce carbon emissions. That kind of “win” has an especially outstanding appeal. Cool Planet has won significant corporate backing from BP, ConocoPhillips, General Electric, and Google among others, and is now looking at opening two new facilities in Louisiana. The logical conclusion for biomass electricity or biochar, from a purely carbon accounting perspective is that we should burn things that grow faster and therefore incur a shorter “carbon debt.” GE eucalyptus perhaps? Clearly it is not very helpful to reduce the whole affair of climate change to counting carbon molecules. Forests, soils, ecosystems all are far more than agglomerations of carbon. They are intricate, multidimensional, interconnected, and complex beyond our imaginings and hence beyond our ability to measure, manipulate, and control. The reductionist mindset that carbon accountants engage with is a dead end that only serves to blind us to the full scope and range of Earth as a whole. It fails to see that this planet is more than the sum of its parts. If we are really serious about preserving life on Earth, we will have to relearn how to envision the whole, embrace humility in the face of our ignorance about how life-supporting earth systems work. No amount of biochar, no climate geoengineering tricks, no technofixes or markets or “private sector engagement” or fancy carbon accounting will be a “win win win” for us. By far the winning strategy would be to allow Earth to restore, regenerate and recover, on her own terms. Continue reading
Corn Residue as a Feedstock for Cellulosic Ethanol
By Kolby Hoagland | September 13, 2013 This week, Biomass Magazine took part in the National Advanced Biofuels Conference & Expo and the Corn Stover Harvest & Transport Seminar , which were held in conjunction at the CenturLink Center in Omaha. I was given the honor to MC the Corn Stover Harvest & Transport Seminar where soil scientists, crops specialists, equipment manufacturers, farmer associations, and numerous other experts from industry and academia candidly discussed how corn residue ought to be harvested and aggregated to maintain soil quality and provide a consistent feedstock for cellulosic ethanol plants. In this week’s DataPoint, I will build on a previous article by Anna Simet and provide an in-depth analysis on the benefits of combining corn residue removal with no/low-till field management. The first panel of the Corn Stover Harvest & Transport Seminar, “From Soil to Pump: The Impact of Organic Matter and Nutrient Loss on Our Farmland,” looked at key considerations of corn residue removal on soil conservation and corn yield improvement. The presenters from ARS, Monsanto, and Iowa Corn provided a succinct research-backed that either too little or too much stover left on a field can have negative effects to subsequent corn crops and soil health. The panelists agreed that no-till and low-till field management schemes are some of the most effective practices for farmers to protect their soil from erosion, soil organic matter volatilization, and nutrient run-off. As average annual corn yields trend upwards, the reduction of corn residue left from the previous year’s grain harvest becomes more important. Corn residue encountered during planting in the spring poses a number of problems to farmers. Fall and spring tillage have historically been practiced to incorporate the previous season’s corn residue back into the soil in order reduce the quantity left on the surface of the field. The prime motivators of plowing corn residue back into the soil are to reduce pathogens that might be in the residue and to encourage better seed to soil contact, which excess corn residue inhibits. Plowing the corn residue back into the field provides a clean and even seed bed for strong stand establishment. Furthermore, tillage schemes have been practiced by generations of farmers and are a proven way to manage residue. The panel acknowledged the historic nature of tillage practice, but also conveyed the negative consequences tillage poses to soil health and yield. Once the residue has been tilled back into the soil, the carbon in the previous year’s corn residue binds nitrogen that would otherwise be available to the current corn crop. Furthermore, the tillage of agricultural soil volatilizes considerable quantities of soil organic matter, destroys soil aggregates, and encourages erosion and runoff. By combining no/low-till practices with stover removal in field management schemes, studies not only show yield increases in subsequent corn crops but improved soil health. Soil aggregates are maintained in the fields soil profile, valuable soil organic matter is prevented from volatilizing to the atmosphere, and healthy amounts of stover are left on the field to protect from erosion and runoff when stover removal and no/low-tillage practices are combined in a field management shceme. The panel determined that pairing crop residue removal with no/low-tillage practices would support farmer’s intent to manage excess crop residue, support soil health, and provide sufficient quantities of feedstock to the burgeoning cellulosic ethanol industry. The in-field variability of soil and the dynamic relationship that corn residue has on positive and negative yield effects necessitate ingenuity and practice. The conclusion of the panel stated that corn stover can be done in a manner that would sustain soil health when paired with no and low-till practices. The experiences gained by farmers supplying Abegnoa Bioenergy Biomass of Kansas, DuPont Cellulosic, and Poet-DSM will support a better understanding of best practices for future suppliers of corn residue to the burgeoning cellulosic ethanol industry. Continue reading